Tubular neighborhood theorem: Difference between revisions

Latest revision as of 20:12, 18 May 2008

This fact is an application of the following pivotal fact/result/idea: inverse function theorem
View other applications of inverse function theorem OR Read a survey article on applying inverse function theorem

This fact is an application of the following pivotal fact/result/idea: existence of smooth partitions of unity
View other applications of existence of smooth partitions of unity OR Read a survey article on applying existence of smooth partitions of unity

This fact is an application of the following pivotal fact/result/idea: Lebesgue number lemma
View other applications of Lebesgue number lemma OR Read a survey article on applying Lebesgue number lemma

Statement

Let $M$ be a submanifold (differential sense) of $\mathbb {R} ^{n}$ , of dimension $m$ . Then, there exists $\epsilon >0$ such that for any point at distance at most $\epsilon$ from $M$ , there is a unique expression of the point as a sum $p+v$ where $p\in M$ and $v$ is a normal at $p$ , with $\|v\|<\epsilon$ .

If we define $U$ as the open subset of $\mathbb {R} ^{n}$ comprising those points of $\mathbb {R} ^{n}$ at distance less than $\epsilon$ from $M$ , then $U$ can be viewed as a concrete realization, in the ambient space $\mathbb {R} ^{n}$ , of the normal bundle to $M$ in $\mathbb {R} ^{n}$ . In the situations where the normal bundle to $M$ is trivial, we see that this gives a natural diffeomorphism $U\cong M\times \mathbb {R} ^{n-m}$ .

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+{{applicationof|inverse function theorem}}
+{{applicationof|existence of smooth partitions of unity}}
+{{applicationof|Lebesgue number lemma}}
 ==Statement==
-Let <math>M</math> be a [[submanifold (differential sense)]] of <math>\R^n</math>, of dimension <math>m</math>. Then, there exists <math>\epsilon>0</math> such that for any point at distance at most <math>\epsilon</math> from <math>M</math>, there is a unique expression of the point as a sum <math>p + v</math> where <math>p \in M</math> and <math>v</math> is a normal at <math>p</math>, with <math>\norm{v} < \epsilon</math>.
+Let <math>M</math> be a [[submanifold (differential sense)]] of <math>\R^n</math>, of dimension <math>m</math>. Then, there exists <math>\epsilon>0</math> such that for any point at distance at most <math>\epsilon</math> from <math>M</math>, there is a unique expression of the point as a sum <math>p + v</math> where <math>p \in M</math> and <math>v</math> is a normal at <math>p</math>, with <math> \| v \| < \epsilon</math>.
 If we define <math>U</math> as the open subset of <math>\R^n</math> comprising those points of <math>\R^n</math> at distance less than <math>\epsilon</math> from <math>M</math>, then <math>U</math> can be viewed as a concrete realization, in the ambient space <math>\R^n</math>, of the normal bundle to <math>M</math> in <math>\R^n</math>. In the situations where the normal bundle to <math>M</math> is trivial, we see that this gives a natural diffeomorphism <math>U \cong M \times \R^{n-m}</math>.